DE7617327U1 - Cylinder lock with multiple key removal for rotary switch - Google Patents

Description

April 21, 1978

Dipl. Ing. Robert Meif> r, "j '* ^: .. ^: ' T '\' ,, '- be 17 441

Patent attorney

6 Frankfurt am Main

Awl dom MOhlborq 16

Bauer Kaba AG, Security Wetzikon

Locking systems, (Switzerland)

Cylinder lock with multiple key removal for rotary switches

The innovation · relates to a cylinder lock with multiple key removal for rotary switches and display of the Switch position through the rotational position of the key channel.

Cylinder locks of this type, in which the directly attached rotary switch, which in the broadest sense of the The term "rotary switch" with its predetermined, limited rotary movements can be used for the most varied of purposes, e.g. for electrical on-off switching or step switching, switching controls of machines or devices or groups of those used to switch shut-off valves, multi-way taps, etc., can only be loaded with a suitable key.

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and this can only be removed when the switch is in the locked position, are already known.

Such cylinder locks can only have a limited number, i.e. only three to a maximum of eight tumblers, with them - based on the full key or Rotor turning circle - also a maximum of only four switch positions with a switching angle of rotation of 90 each can still be realized economically, since the drilling pattern of the tumblers multiplied in the stator according to the number of key withdrawals, i.e. with their number the number of Stator bore rows must be multiplied. Therefore, these well-known cylinder locks with multiple trigger, which - coaxially assembled with the actual rotary switch as a switch unit - also called "switch cylinder" for short are often inadequate with regard to the switching programs to be implemented, due to the low Number of tumblers not very secure and due to the limited variation options, i.e. the permutation restriction, also not usable for locking systems. Cylinder locks with intermediate washers can generally not be provided with multiple deductions for the key, as these discs would otherwise be carried away, which is why these disadvantages are even more significant.

7617327 011178 I.

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The purpose of the invention is to remedy the aforementioned disadvantages.

Accordingly, the innovation concerns. a cylinder lock with Multiple key withdrawal of the type mentioned, which is characterized according to the invention in that the The rotor is provided with a shift gate that cannot be rotated in relation to it and can be displaced via this with a in the stator mounted locking slide is coupled so that it can be displaced via the shift gate when the rotor rotates in the stator is that the stator is in a stationary part of the switch, the number corresponding to the number of switch positions of locking openings, is rotatably but axially immovable and that the in each case in the key withdrawal rotational position standing rotor in a locking opening of the stator engaging locking slide by an in stator mounted compression spring, which is supported on the lock cylinder sleeve, via the shift gate in its blocking position, in which the stator is secured against rotation in the stationary switch part by the locking slide and this from this (only) by turning the rotor from its key withdrawal position via the shift gate can be withdrawn against the pressure of the compression spring, the number of locking openings being independent of the arrangement and Number of tumblers of the cylinder lock is selected.

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A preferred embodiment of the cylinder lock according to the invention is that in addition to the stator Locking slide a spring-loaded switch latching element is mounted and the stationary switch part in one to the rotor axis of rotation vertical plane a number of locking openings corresponding to the number of locking openings for receiving the Having switching latching member, the switching latching member in each rotational position of the secured by the locking slide The stator is locked into a locking opening of the stationary switch part and thereby the rotary position of the stator and rotary switch is fixed in the associated switch position, or that a corresponding switch latching device,

- ■ .....- = - the cylinder lock

downstream, housed in the switch itself and arranged between a rotatable and a stationary switch part is.

f * In the drawing is an exemplary embodiment of the innovation

shown schematically in different phases of rotation of the cylinder lock. Show it:

Fig. 1 shows a cylinder lock without a key in an engaged switching position, in a cross section according to the line I-I, partly along the line Ia-Ia, of Fig. 2,

FIG. 2 shows the lock according to FIG. 1, in a longitudinal section along the line II-II in FIG. 1,

3 shows the lock according to FIG. 2, in a top view according to arrow III in FIG. 2,

4 shows the lock according to FIG. 3, in the rear end view according to the arrow IV in FIG. 3,

Fig. 5 shows the cylinder lock with inserted key after turning the unlocked rotor up to Stop of the locking slide, which has been withdrawn from a locking opening in the grid sleeve at the same time the Schliesszvlinderhülse, in a cross section along the line V-V of Fig. 6,

6 shows the lock according to FIG. 5, in a longitudinal section along the line VI-VI in FIG. 5,

7 shows the cylinder lock with key after further rotation of the rotor together with the stator and disengagement of the switching latch from a locking opening of the grid sleeve, in a cross section along the line VII-VII of the Fig. 8,

8 shows the lock according to FIG. 7, in a longitudinal section along the line VIII-VIII in FIG. 7,

9 shows the cylinder lock with key after further rotation of the rotor and stator and the engaging of the Switching locking element in the next locking opening of the grid sleeve when it is still withdrawn from this Lock slide, in a cross section along the line IX-IX of Fig. 10,

FIG. 10 shows the lock according to FIG. 9, in the side view according to the arrow X in FIG. 9,

11 shows the cylinder lock after the rotor has been rotated back into its withdrawal rotational position and the locking slide has been pushed out in the locking opening of the grid sleeve and key removal, in a cross section along the line XI-XI of Fig. 12,

FIG. 12 shows the lock without a key according to FIG. 11, in a side view according to the arrow XII in FIG. 11,

13 shows the rotor of the cylinder lock according to FIGS. 1 to 12, in a three-dimensional view, and

14 shows the locking slide of the cylinder lock according to FIG. 1 to 12, in a three-dimensional view.

In Fig. 1 contains a cylinder lock 1 (also called "lock cylinder" referred to) initially conventional lock parts, i.e. a stator 2, a rotor 3 rotatably mounted therein,

arranged in rows in the longitudinal direction of the locking cylinder 1 Tumbler groups 4 (see. Fig. 2) and a lock cylinder sleeve 5. The lock cylinder 1 can be rotated as a whole, but axially immovable in a lock cylinder sleeve 5 surrounding it, here designed as a ratchet sleeve stationary part 6 of the actual switch stored. The grid sleeve 6 is here on its rear sleeve base (see. Fig. 2) provided with two threaded holes 7 and is from behind by means of two screws on the actual Switch, e.g. attached to a stationary switch plate 8, as is only indicated in FIG. The rotor 3 has at its rear end a shift gate 9 (see. Also Fig. 2 and 13), via which he with one in two radial Stator bores 2b displaceably mounted locking slide 10 (see. Also Fig. 2 and 14) is constantly coupled. In the in The rotational position of the rotor 3 shown in FIG. 1, the locking slide 10 lies with a flat surface 15 on a flat surface 16 the shift gate 9 on. Through the shift gate 9, the locking slide 10 is turned out of its in when the rotor rotates Fig. 1 shown blocking position, in which he is with a peg-shaped Approach 11 through a radial opening 5a of the lock cylinder sleeve 5 into a radial locking opening 12 on the The circumference of the ratchet sleeve 6 engages, withdrawn to unlock the lock cylinder 1 with respect to the ratchet sleeve 6, whereby the lock cylinder 1 is released to its rotary movement and thus to operate the switch, like this will be explained in more detail later. One as

7617327 09.1178

Locking slide spring 13, which is designed as a compression spring, is held in a sleeve-like foot section 14 of the locking slide 10, is supported with its free end on the inner wall of the lock cylinder sleeve 5 and presses in the one shown in FIG In the rest position of the lock cylinder 1, the locking slide 10 with its surface 15 against the surface 16 of the shift gate 9. As a result, the locking slide 10 is held in its locked position. Here the lock cylinder 1 is e.g. for four Switch positions set up, i.e. its grid sleeve 6 is on the circumference in a position perpendicular to the lock cylinder axis Provided level with four locking openings 12 for switching rotation angle travels of 90 ° each. In addition to the locking slide 10 a second spring-loaded latching element is housed in the lock cylinder 1, which is designed here as a ball catch and is denoted by 17. The ball catch 17, which is activated by a catch spring 18 mounted in the stator 2 radially outwards against the edge of a through opening 5b provided on the circumference of the lock cylinder sleeve 5 is pressed, .supports the locking or unlocking of the lock cylinder 1 in or opposite the locking sleeve 6 and thus in the actual switch. In Fig. 1, in which the rest position of the lock cylinder 1 is shown, is the ball catch 17, like the locking slide 10, in its locked position, the catch ball 17 in a radial locking opening 19 of the grid sleeve 6 engages. Corresponding to the four switch positions of the lock cylinder or the actual Schaxter is the grid sleeve 6, except

the four locking openings 12 for the locking slide 10, provided with four such locking openings 19 each for a switching angle of rotation of 90 °, which are also arranged in a common plane perpendicular to the lock cylinder axis, which lies in front of the plane of the four locking openings 12, as shown in FIG Fig. 2 clearly emerges. Here the four locking openings 19 and the four locking openings 12 are arranged in pairs in two mutually perpendicular longitudinal center planes of the lock cylinder 1 (see FIG. 2). In each of the four switching positions of the lock cylinder 1 or switch, the locking slide 10 and the ball catch 17 are in their locking or latching position and at the same time the rotor is in its locked rotational position, in which a suitable key is inserted or removed in the keyway 20 of the rotor 3 this can be deducted. While the locking slide is only used to lock or unlock the lock cylinder 1 or its stator 2 in the ratchet sleeve 6, the locking element 17, which is designed here as a ball catch, causes the actual on and off operation of the switch cylinder. A plate-shaped rotor holder 21, which is inserted from the outside into a narrow slot 22, a so-called "recess" milled in the stator 2 perpendicular to the lock cylinder axis, and engages in a corresponding slot 23 of the shift gate 9, secures the rotor 3 against axial displacement in the stator 2 (see also Fig. 3 _f 5, 7, 9 and 13). The shift gate 9 has, in addition to the slot 23, as a recess

7617327 09.1178

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still have two further slots 23a and 23b, which are connected to the Slot 23 lie in a common plane perpendicular to the rotor axis (cf. also FIG. 2 and in particular FIG. 13). the both slots 23a and 23b, which have no function, have arisen from the fact that the rotor 3 is rotated, while the milling blade is being pierced.

2 shows two rows of tumblers 4, these two tumbler rows in a common axial plane of the lock cylinder 1, but are offset from one another in the longitudinal direction. For the sake of greater clarity FIG. 2 shows only one of the tumblers 4 with its tumbler pin 4a, its counter tumbler 4b and spring 4c. Since the rotor 3 is in a switching position of the switch, i.e. in a rotational position for key withdrawal or insertion of the When the key is in the keyway 20, the counter-locking devices 4b engage from the outside into the associated radial rotor bores a, whereby the rotor 3 in the stator 2 is secured against rotation and thereby at the same time a switch operation prevented by unauthorized persons. The arrangement of the tumbler rows and the number of tumblers 4 can be independent can be selected by the number of switch positions. By a locking ring 24, here a so-called "Seeger ring" is the stator 2 and thus the entire lock cylinder 1 against axial displacement to the front in the raster sleeve 6 secured. A drive arm 25 is by means of a pin

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26 and articulated to the stator 2 in a radial slot 27 of a cylindrical stator attachment 2a transmits its rotary movement to a rotatable part 28 of the actual lock cylinder axis which is arranged coaxially with the lock cylinder axis Switch, preferably on a switch shaft. Furthermore, FIG. 2 shows the essentially U-shaped shape of the locking slide 10, the shift gate 9 of the rotor 3 in the recess of the caused by the U-shape Locking slide 10 protrudes and thereby the permanent coupling of rotor 3 and locking slide 10 or the permanent Effective connection of these two parts is ensured during the rotation of the rotor 3 in the stator 2. Also is in Fig. 2 with 6a indicated that the stationary one provided with the locking and latching openings 12 and 19, respectively Switch part instead of forming it as a grid sleeve 6 and this on its rear side by means of screws on a stationary one to fasten the front switch plate 8, the switch housing itself could also be directly, the Locking or locking openings could be designed as blind holes.

In Fig. 3 and 4 is secured in the key is withdrawn by the locking slide 10 against rotation in the sleeve 6 Raster lock cylinder 1 in the embodiment shown in Figures 1 and _2: i. Initial rotational position, in which at the same time the rotor 3 by the

; Guard locking 4 blocked, i.e. against rotation in the stator 2

is secured, in the plan view from above or in the

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rear end view shown.

5 shows the lock cylinder 1 with the key 29 inserted after the unlocked rotor 3 has been rotated out of its inserted rotational position (cf. 4 arranged at the cylindrical parting line between rotor 3 and stator 2, thereby releasing rotor 3 to rotate. The rotor 3 was then rotated by the angle of rotation oC "until the locking slide 10, which is mounted displaceably in the radial stator bores 2b and which simultaneously moves from the shift gate 9 via a pressure transfer point 30 on its surface 16 against the pressure of the locking slide spring 13 during the rotor rotation the locking opening 12 of the raster sleeve 6 has been withdrawn, with the edge of its sleeve-like foot section 14 hits the stop points 31 of the lock cylinder sleeve 5, which becomes noticeable when the key 29 is turned. The stator 2, which did not take part in this rotor rotation, is still - as in 1 - is locked in the snap-in sleeve 6 by the ball catch 17 engaged in the latching opening 19, so that the switch has also retained its previous switch position the stator 2, beyond the angle of rotation oC no further in the direction of the

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Arrow D can be rotated.

FIG. 6 shows the lock cylinder 1 in the previously described rotational phase according to FIG. 5 in a longitudinal section. The slide gate spring 13 is due to the rotation of the rotor 3 by the retracted from its locked position at the same time Lock slide 10 has been compressed. Stator 2 including lock cylinder sleeve 5, drive arm 25 and its pivot pin 26 and the switch shaft 28 are still in the previous rotational position (cf. FIG. 6 with FIG. 2). Only the rotor 3 together with the shift gate 9 has changed its rotational position and thereby the locking slide 10 in its unlocked position withdrawn.

In FIG. 7, the rotor 3 is from the rotational position shown in FIG. 5, but now together with the stator 2, in the direction of arrow D has been rotated further. This causes the stator 2 (including the lock cylinder sleeve 5) to rotate at the same time comes about that the shift gate 9, which with its surface at the pressure transmission point 30 of the locking slide 10 on this when the rotor 3 continues to rotate, the one that is already in contact with the stop points 31 of the lock cylinder sleeve 5 Lock slide 10 can not move any further, which is in the now co-rotation of the stator 2 via Effect pressure transfer point 30, locking slide 10, stop points 31 and wall of the radial stator bore 2b got to. During and as a result of the rotation of the stator 2, the ball catch 17 is against the pressure of the catch spring

disengaged from the locking opening 19 of the grid sleeve 6 and is now in the direction of rotation D on the way to the next Latch opening 19, while the locking slide 10 is still retracted into its unlocked position.

FIG. 8 shows the lock cylinder 1 in the further rotational position of the rotor and the rotatable position described above with reference to FIG Stator in a longitudinal section. When the stator 2 rotates, the drive arm 25 and therefore also the switch shaft rotated, but the switch is not yet locked in its new switch position.

According to FIG. 9, the rotor 3 including the stator 2, ie the entire lock cylinder 1 from the rotational position shown in FIG Snap spring 18 is engaged in the next latching opening 19 of the ratchet sleeve 6 and thereby the switch has already been brought into its next switching position. With this further rotation of the lock cylinder 1, however, the locking slide 10, which is now with its locking pin 11 in front of the next locking opening 12 of the locking sleeve 6, still retracts into its unlocked position, and also the stop and transmission conditions on or between shift gate 9, Locking slide base 14 , lock cylinder sleeve 5 and wall of the radial stator bore 2b with the pressure transfer point 30 and the

Attachment points 31 have remained unchanged. In this respect, therefore, FIG. 9 corresponds completely to FIG. 7, as, incidentally, also to FIG. 5. As can be clearly seen from a comparison of FIG. 9 with FIG. 7, the rotor 3 is in this further rotation, in which the locking slide 10 has already been brought in front of the next locking opening 12, by the angle of rotation oC (see also FIG. 5 ) has been rotated beyond the new ί locking position of the ball catch 17.

FIG. 10 shows the rotated according to FIG. 9 even further

Lock cylinder 1 with the key 29 still inserted in a side view. With this further rotation, with the the stator 2 rotates with it and the ball catch 17 in the embodiment of a lock cylinder explained here for four switch positions the smallest possible switch rotation path of 90 between two consecutive ones Has covered locking openings 19 (see. Fig. 9 with Fig. 1), was with the rotating rear stator attachment 2a at the same time also the drive arm 25 rotated, this at the same time also the switch shaft 28 by the switching path from 90 to has turned the next switch position (see Fig. IQ with Fig. 2).

11 shows in cross section the lock cylinder 1 after only the rotor 3 has been rotated back by the rotation angle oC (cf. FIG. 9) in the direction of the arrow Dr into its new insertion or withdrawal rotational position for the key 29 and after

its deduction. The locking slide spring 13 has via locking slide 10, i.e. locking slide foot 14, as well as a pressure transmission point 30 (cf. FIG. 9) and shift gate 9 move the rotor 3 until the two surfaces 15 and 16 come into contact with one another rotated back and at the same time the locking slide 10 in its new locking position, in which its locking pin 11 in the next locking opening 12 is locked, pushed back. Only after the rotor 3 has been put into its new one in this way Key withdrawal rotational position turned back and at the same time the locking slide 10 has been brought into its new locking position was, the key 29 could on this new switch position from the key channel 20, which is now the new switch position indicates to be deducted. As a result, the rotor 3 is now back through the tumbler groups 4 (see. Fig. 2) secured against rotation in the stator 2, while the locking slide 10 by the shift gate 9 of the rotor 3 in his Locked position against pushing back and the lock cylinder 1 through the locking slide 10 in the ratchet sleeve 6 against Rotation is secured.

FIG. 12 shows the lock cylinder 1 in the rotational phase previously described with reference to FIG. 11 with the key removed. The rotary switch is now after the stator 2 and rotor 3 have rotated through the switching path of rotation of 90 ° (cf.Fig. Hu. 12 with Fig. 1 or 2) in its new switch position.

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locks in place and secured against unauthorized actuation by third parties by the locking slide 10 and the tumblers 4. the new rotational position of the key channel 20 shows the associated new switch position in the usual way on one of the Lock cylinder 1 comprehensive index plate arranged on the front of the switch, this with one of the different switch positions corresponding number of circular tick marks is provided.

In Fig. 13, the rotor 3 is shown with its shift gate 9 in a three-dimensional view. The backdrop 9 is off the cylindrical rotor body 3 milled out. In the shift gate 9 is the slot 23 for receiving the rotor holder 21 (cf. also FIG. 5) produced in the so-called "piercing process", so that in the same plane perpendicular to the Rotor axis in the shift gate 9 as a recess two further slots 23a and 23b have arisen. The milled one Key channel 20 extends to the rear face of the shift gate 9 (see. Fig. 2, 6 and 8).

14 shows the locking slide 10 in a three-dimensional view. Like the rotor 3, it is made of a cylindrical one Blank produced by turning and milling. The U-shaped recess between the cylindrical end sections of the locking slide 10 was created by milling out. The locking pin 11 is turned on the one cylindrical end section, while the other sleeve-like cylindrical end portion, which forms the locking slide base 14, for receiving the locking

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slide spring 13 with a turned or drilled cylindrical opening 14a is provided.

With the lock cylinder described above, in contrast to the conventional lock cylinder, this is now for Actuation of a lock bolt or a rotary switch used, now also the stator 2 rotatably mounted and the angular path of the rotor 3 relative to the stator 2 no longer depends on the radial position of the rows of tumblers 4 (cf. Fig. 2) depends, but only on the size of the retraction stroke of the locking slide 10 until it is placed on the inner wall of the lock cylinder sleeve 5 (see. Fig. 1 and 5). The tumbler pins also act on the lock cylinder 1 4a of the rotor 3 no longer when switching from one switching position to any other, as in the conventional one Switch cylinder, each with a different row of counter-locking devices assigned only to this other switch position of the stator together, but always only with one and the same series of counter-locking devices 4b (see. Fig. 2), because the stator 2 with each switching process, i.e. with every possible switching rotation path, in each case after retraction of the locking slide 10 is only rotated together with the rotor 3, i.e. by this on the relevant switching path is taken in the direction of rotation. In contrast to the conventional locking cylinder, for whatever purpose it is may always be used, the rotor 3 leads here during the switching process, apart from that for the retraction or

7617327 011178

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Re-advance of the locking slide 10 necessary, but relatively small angle of rotation path with respect to the stator 2, relative to this no rotational movement at all. Unlike the conventional switch cylinder, stay here thus also the key withdrawal rotational position of the rotor 3 relative to the (rotated) stator 2 for each switching position of the Rotary switch unchanged.

The switching characteristics of a lock cylinder 1 equipped with the lock cylinder 1 previously explained with reference to the drawing The rotary switch, viewed in slow motion, as it were, is as follows:

First of all, the inserted key 29 can (with the rotor 3 for itself) against the low resistance rotate the slide spring 13 relatively easily (see Fig.l), until suddenly and clearly noticeable for the operator the resistance to rotation when the locking slide is put on 10 on the lock cylinder sleeve 5 (see. Fig. 5), with the simultaneous rotation of the stator 2 and the resulting disengagement of the ball catch 17 from the locking sleeve 6 (see. Fig. 7) is considerably greater, because now, when the key is turned, the considerably greater disengagement resistance of the ball catch 17 is added. If you turn the key further, the catch locks

7617327 811117 «

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Ball 17 under the pressure of the snap spring 18 suddenly into the next locking opening 19 of the locking sleeve 6 (see FIG. 9), which is not only important for the operator suddenly sharply decreasing resistance to turning the key, but also, and above all, the snapping sound of the The locking of the snap ball and thus the rotary switch in its new switch position can be clearly seen. As a result the relatively large resistance to rotation on the key that causes the snap ball 17 to disengage from the previous locking opening 19 had to be overcome, but the key is taken by the operator after the snap ball has clicked into place in the new switch position - but now again only ■ against the relatively low resistance of the locking slide spring 13 - beyond the new gear shift position reached - involuntarily until it is again clearly noticeable The stop of the locking slide 10 on the lock cylinder sleeve 5 is rotated further (see FIG. 9) and only then no torque at all exerted by the operator on the key, so that the rotor 3 under the Pressure of the slide spring 13 returns by itself in the key withdrawal rotational position, after which the key from can be withdrawn by the operator.

For the "soft" movement sequence of the gate valve actuation and the comparatively "hard" characteristics the actual switch latching by the ball catch 17, it is by no means necessary that the catch spring 18

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is harder than the slide gate spring 13, because these two functions of the switching process only affect the different ones Size of the two associated, effectively applied by the operator on the key bow Torque matters.

Various deviations from the embodiment of the lock cylinder shown in the drawing and explained above are possible. For example, the actual function downstream of the locking slide 10 or its actuation could be used Lock cylinder latching, i.e. the switching latching element used for this purpose (ball catch 17) with associated latching openings 19 housed in the actual switch itself arranged downstream of the lock cylinder 1, i.e. only there between be arranged a rotatable and a stationary switch part. Also, instead of the one with the blocking and locking openings 12 and 19 provided stationary switch part as a ratchet sleeve 6 and this at its rear To fasten the case base by means of screws on a stationary front switch plate 8 (see. Fig. 2) for this purpose as well the switch housing can be used directly itself, i.e. the lock cylinder sleeve 5 can be rotatably mounted in it, as is already indicated in Fig. 2 with 6a, the radial locking and latching openings now in the Switch housings would have to be arranged themselves and - instead of as through openings - also designed as blind holes

could evaluate. Furthermore, the tumbler groups 4 need by no means, as shown in FIG. 2 only as an example is to be arranged in a plane perpendicular to the flanks of the key channel, rather they could can also be placed in other longitudinal center planes of the lock cylinder 1, because the placement of the rows of tumblers depends on the locking mechanism provided in the rear part of the lock cylinder, i.e. from the arrangement of the Shift gate 9, the locking slide 10 and the locking openings 12, completely independent, but also largely independent of the arrangement of the switching latching member 17 and its latching openings 19. Because these in the stator 2 only have little space The shifting latching device requiring a load can be used both in the associated plane perpendicular to the lock cylinder axis as well as in the associated longitudinal center plane of the lock cylinder between the tumblers will. Instead of the locking openings 19 in the same mutually perpendicular longitudinal center planes of the lock cylinder to be arranged, in which the locking openings 12 are already provided for the locking slide 10 (see. Fig. 1), could they can also be arranged in any other two planes that are perpendicular to one another, because also the switching latch member 17 even in the stator 2 by no means in the direction perpendicular to the axis of the receiving bore 2b for the locking slide 10 The longitudinal center plane of the stator 2 must be supported, but

could also be arranged in any other longitudinal center plane.

The novelty- is therefore not related to the previously based on the drawing explained embodiment bound, but the details of the execution can be included in the innovation. can be varied.

The main advantage of the above-described cylinder lock with multiple key removal for rotary switches is there in the fact that the lock cylinder is no longer limited to just three to a maximum of eight tumblers, but can be designed as a full-fledged cylinder without any permutation restriction, with all one or multi-row pen cylinder or plate cylinder possible are. Another advantage is that the switch cylinder no longer has a maximum of four, but now up to twelve switch positions (with a smallest switching angle of 30 °) are possible because this is one of the Task of identification between key and lock cylinder represent independent secondary functions and therefore their number independent of the arrangement and number of Guard locking can be selected in the lock cylinder. The greatest possible number of switch positions is practical only by the given lock cylinder diameter on the circumference of the stationary switch part or the Grid sleeve considering the strength requirements structurally still to be accommodated number of locking

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and locking openings limited what for a given diameter of these openings leads to a smallest hole pitch angle of approx. 30.

Claims (1)

Il · »· I ···· I f If · «« Jl I - 25 protection claims 1. Cylinder lock with multiple key holder for rotary switches and display of the switch position through the rotation position of the key channel / characterized in that the rotor (3) provided with a non-rotatable shift gate (9) and displaceable via this with a in the stator (2) mounted locking slide (10) is coupled that this when the rotor (3) rotates in the stator (2) via the shift gate (9) is displaceable that the stator (2) in a stationary switch part (6), which has one of the number of switch positions has a corresponding number of locking openings (12), is rotatably but axially immovable and that the rotor (3), which is in the key withdrawal rotational position, is inserted into a locking opening (12) of the stationary switch part (6) engaging locking slide (10) through a mounted in the stator (2) and attached to the lock cylinder sleeve (5) supporting compression spring (13) over the shift gate (9) in its blocking position, in which the stator through the locking slide (10) is secured against rotation in the stationary switch part (6), is held and from this (only) by rotation of the rotor (3) from its key withdrawal rotational position via the Shift gate (.9) retractable against the pressure of the compression spring (13) is, the number of locking openings (12) regardless of the arrangement and number of tumblers (4) of the Cylinder lock (1) is selected. 7617327 09.1178 2. Cylinder lock according to claim 1 / characterized in, that in the stator (2), in addition to the locking slide (10), a spring-loaded switch latching element (17) is mounted and the stationary switch part (6) one of the number of blocking openings in a plane perpendicular to the rotor axis of rotation (12) has a corresponding number of latching openings (19) for receiving the switching latching member (17), the Switching latch member (17) in each rotational position of the stator (2) secured by the locking slide (10) in a latching opening (19) of the stationary switch part (6) engaged and thereby the rotational position of the stator (2) and rotary switch is fixed in the associated switch position, or that a corresponding switching locking device dem Downstream cylinder lock (1), housed in the switch itself and between a rotating and a stationary one Switch part is arranged. 3. Cylinder lock according to claim 1, characterized in that ■ that the locking slide (10) is cylindrical in outline and is axially displaceable in two coaxially aligned radial bores (2b) of the stator (2), that the locking openings (12) in a direction perpendicular to the rotor axis of rotation Plane on the circumference of the cylinder receiving opening of the stationary switch part (6) are arranged radially, and that in a the compression spring (13) mounted on the two stator bores (2b) is supported on the circumference of the lock cylinder sleeve (5). 7617327 09.1178 4. Cylinder lock according to claim 1, characterized in that the shift gate (9) is arranged at the rear end of the rotor (3) and is formed in one piece with this, the key channel (20) on the rear face of the shift gate (9) opens. 5. Cylinder lock according to claims 1, 3 and 4, characterized in that that the shift gate (9) protrudes from the front into a recess of the locking slide (10) that the with the Recess U-shaped locking slide (10) is provided on a lock-side leg with a locking pin (11) and its other leg (14) serving the locking slide drive is designed as a sleeve-like slide foot and for receiving the compression spring (13) serves that the locking slide base (14) and the shift gate (9) to fix the by the compression spring (13) the locking slide (10) pushed out into its locking position are provided with mutual stop surfaces (15 or 16) and that the locking slide (10) over a transmission pressure point (30) common to these two surfaces (15, 16) up to the stop of the locking slide base (14) can be withdrawn into its unlocked position at stop points (31) of the lock cylinder sleeve (5) is. 6. Cylinder lock according to claims 1, 4 and 5, characterized in that that the shift gate (9) in cross section in essentially approximately in the form of an isosceles triangle circumscribed by the circumferential circle of the rotor (3) and the locking-side locking slide leg with its locking pin (11) is arrow-shaped in the same cross-sectional plane to the shift gate (9) and that the base of the gate cross-section triangle a generating line of the link stop surface and the two triangular cathets generating line from opposite the Perimeter of the rotor (3) formed receiving pockets for the retraction of the locking slide (10) from its locking position in Direction of the shift gate (9) are moving locking-side locking slide legs (see. Fig. 1 and 5). 7. Cylinder lock according to claims 1, 3 and 4, characterized in that that the stationary switch part (6) is designed as a ratchet sleeve, this from the rear onto the lock cylinder sleeve (5) pushed on and on the circumference of its jacket with the blocking openings designed as radial through openings (12) is provided that for fastening the cylinder lock (1) to the switch housing (8) threaded holes (7) in the rear Sleeve base are provided and a cylindrical stator extension (2a) penetrating this for the coupling (25, 26, 27) of the stator (2) with a rotatable switch part (28) arranged coaxially to the lock cylinder axis and that the stator (2) in the grid sleeve (6) against axial displacement to the front by a behind the sleeve base on Stator approach (2a) arranged securing element (24) is fixed. 7617327 09.1178 8. Cylinder lock according to Claims 1 and 2, characterized in that that the switching locking element (17) is designed as a ball catch and the catch ball in the stator (2) or rotatable switch part is mounted. 9. Cylinder lock according to claims 1, 7 and 8, characterized in that that the catch ball, which is mounted in the stator (2) and loaded by a radially arranged catch spring (18) (17) in their latched position on an edge serving as a stop on the jacket of the lock cylinder sleeve (5) radially arranged through opening (5b) is supported. 10. Cylinder lock according to claims 1 to 4 and 7 to 9, characterized in that the through openings formed Latch openings (19) for the snap ball (17) are arranged on the jacket of the grid sleeve (6) and that on the cylinder lock (1) the plane common to the ball catch (17) and its locking openings (19) in front of the locking slide (10) and its locking openings (12) is arranged in common plane. 11. Cylinder lock according to claims 1, 3 and 4, characterized in that that the lock cylinder sleeve (5) at the rear end of the sleeve jacket is in the locking openings (12) of the 7617327 09.1178 <- 30 - stationary switch part (6) common plane arranged radial through opening (5a) or one up to the rear Elongated recess extending through the edge of the sleeve for the passage through the lock cylinder sleeve (5) has a locking slide (10) pushed out into a locking opening (12). 12. Cylinder lock according to claim 1, characterized in that the rotor (3) against axial displacement in the stator (2) by a laterally embedded rotor holder arranged in a plane perpendicular to the rotor axis (21) is secured. 13. Cylinder lock according to claim 12 and one of claims 4 to 11, characterized in that the plate-like The rotor holder (21) engages in a slot (23) in the shift gate (9) designed as a rotor attachment. May 17, 1976
Jr / ae / lf 7617327 09.1178